A hair clipper has a vacuum system for collecting hair debris created by the cutting blades. air flow through an adjustable air inlet is divided into multiple paths, including at least one primary flow path and at least one separate secondary flow path. A debris trap intersects both the primary air flow path and the secondary air flow path. The primary flow path allows air flow through a first path to be higher than a secondary air flow through the second path before debris accumulates in the debris trap. The primary air flow decreases as debris accumulates in the primary air flow path and the secondary air flow approaches and perhaps exceeds the primary air flow, whereupon some debris accumulates in the secondary air flow path as air is diverted through the secondary air flow path.
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1. A hair clipper comprising a housing, cutting blades secured to the housing outside of the housing, and a vacuum system having:
an air flow generator in the housing,
an air inlet adjacent to the cutting blades leading inside the housing, the air flow generator creating a total air flow that draws air from the cutting blades into the housing,
an air exhaust in the housing that releases the total air flow under pressure created by the air flow generator, and
a debris chamber between the air flow generator and the air inlet, the debris chamber having a primary air flow path and at least one secondary air flow path,
wherein a primary air flow through the primary air flow path is higher than a secondary air flow through the secondary air flow path before debris accumulates in the debris trap, the primary air flow decreasing as debris accumulates in the first air flow path, whereupon some debris accumulates in the secondary air flow path as air is diverted through the secondary air flow path, and
wherein the debris chamber includes a first screen perpendicular to the primary air flow path, the primary air flow passing through the first screen,
the first screen having a first edge and a second edge,
a second screen adjacent the first edge and perpendicular to the first screen, and
a third screen adjacent the second edge and perpendicular to the first screen, the secondary air flow being divided between the second and third screens and passing through the second and third screens, wherein the debris chamber has a hinged piece and a fixed piece that share a hinge on one end and form the air inlet on the other end, wherein the hinged piece has a set of bumps and the fixed piece has a set of corresponding holes, wherein the set of bumps and the set of corresponding holes are on the other end, whereby a size of the air inlet is manually adjustable, the size of the air inlet being determined by inserting selected bumps into selected holes.
2. The hair clipper of
a switch assembly for controlling power to the air flow generator; the switch assembly having
an electrical switch secured to the housing;
a switch panel forming part of the housing; and
a switch actuator that controls the electrical switch,
the switch actuator having a yoke inside the housing and a thumb switch outside of the housing, the yoke and the thumb switch being secured to each other through an opening in the switch panel,
the switch actuator further having an opening for insertion of the electrical switch.
3. The hair clipper of
4. The hair clipper of
5. The hair clipper of
6. The hair clipper of
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This invention relates to vacuum systems for hair clippers, and more particularly, to debris traps for hair clipper vacuum systems, and adjustable air inlets for hair clipper vacuum systems.
Conventional vacuum systems for hair clippers have a debris trap that catches hair fragments as the hair is cut. However, airflow decreases as debris accumulates in the trap, which reduces airflow and inhibits waste accumulation Thus, there is a need for debris traps that maintain better waste accumulation as the trap fills with debris.
Hair clippers and trimmers sometime create cut long hair strands. At other times, they create small debris, such as beard stubble. Conventional vacuum systems for hair clippers have a fixed air inlet adjacent the cutting blades to catch all of the debris. However, a large air inlet draws large debris well, but small debris can be lost because negative air pressure at the inlet is relatively low. A small air inlet creates a strong vacuum, which attracts small hair particles, but longer hair can get stuck in the air inlet, because it is small. Accordingly, there is a need for air inlets for vacuum systems for hair clippers that can be adjusted to collect different types of debris well.
Accordingly, one object of this invention is to provide a new and improved vacuum system debris trap for hair clippers that maintain better waste accumulation as the trap fills with debris.
Another object is to provide vacuum systems for hair clippers that collect different types of debris well.
In keeping with one aspect of this invention, a hair clipper has a housing, cutting blades secured to the housing outside of the housing, and a vacuum system for collecting hair debris created by the cutting blades. An air flow generator such as a motor with a fan is provided in the housing. An air inlet adjacent the cutting blades leads inside the housing, the air flow generator creating a total air flow that draws air from the cutting blades into the housing.
Inside the housing, the total air flow is divided into multiple paths, including at least one primary flow path and at least one separate secondary flow path. The housing has at least one air exhaust opening through which the total air flow is released after the air passes the air flow generator.
A debris trap is located between the air flow generator and the air inlet. The debris trap intersects both the primary air flow path and the secondary air flow path. The primary flow path has an effective primary opening that is larger than an effective secondary opening in the secondary airflow path, which can be one or more actual paths.
The primary flow path is preferably in a straight line from the air inlet to the air flow generator, which together with the larger primary opening, allows air flow through the first path to be higher than a secondary air flow through the second path before debris accumulates in the debris trap. The primary air flow decreases as debris accumulates in the primary air flow path and the secondary air flow approaches and perhaps exceeds the primary air flow, whereupon some debris accumulates in the secondary air flow path as air is diverted through the secondary air flow path.
In keeping with another aspect of the invention, the air inlet adjacent the cutting blades can be adjustable to selectively present a small opening for higher air flow and better trapping of small debris, and a larger opening for collecting relatively large debris when needed.
The above mentioned and other features of this invention and the manner of obtaining them will become more apparent, and the invention itself will be best understood by reference to the following description of an embodiment of the invention taken in conjunction with the accompanying drawings, in which:
As seen in
The reciprocating blade 16 is driven back and forth by a motor 30 (
A vacuum system includes another motor 40 having a fan 42 that generates air flow in the housing, as will be described. The motor 40 is also powered by the battery 32 through the switch 34. The switch 34 is part of a switch assembly that controls power to the motors 30 and 40, and includes an actuator 35. The actuator 35 has a yoke 37 inside the housing 12 and a thumb switch 39 that rests outside of the housing 12. The yoke 37 and thumb switch 39 are of one piece construction. The switch assembly also includes the switch panel 15 that is secured to the bottom case 11 of the housing 12 using screws in screw studs 17 (
The vacuum system has a removable debris chamber 50, shown removed and exploded in
The debris chamber 50 has a debris trap 60 that accumulates debris in the chamber 50 and prevents the debris from reaching the motor and exhaust. The trap 60 has a frame 62 with three sides 64, 66 and 68. The side 64 has an edge 71 adjacent the side 66, and an edge 73 adjacent the side 68. An opening is provided in each side 64, 66 and 68, with mesh screens 70, 72 and 74, respectively. The sides 66 and 68 and their respective screens 72 and 74 are preferably perpendicular to the side 64 and its screen 70, and parallel to each other.
The debris on chamber 50 has a pair of rails 80 that slide under a corresponding pair of rails on top lid 82 for mating the debris chamber 50 with the housing top lid 13. Bumps 83 pass over raised portions 90 in the top lid 13 to further secure the debris chamber 50. The rails also facilitate removal of the debris chamber 50 for cleaning. The walls of the chamber 50 are appropriately flexible for adequate securement and removal without excessive effort.
The trap 60 is secured in the debris chamber 50 by placing it inside of L-shaped grooves 85 in the chamber 50 and engaging protrusions 84 (in the sides 66, 68) over openings 86 (in the chamber 50). Dash lines 87 indicate how the trap 60 is installed.
The hinged portion 54 and fixed piece 52 share the hinge 56 on one end, and a set of bumps 94 (on the hinged portion 54) and holes 96 (on the fixed piece) on the other end. The throat 58 is generally formed along edges 61, outlined in bold lines in
Air flow in the vacuum system will be described primarily in connection with
In
Referring now to
The switch panel 15 has an opening 126, seen in
Referring now to
The yoke 37 surrounds the peg 120 with a first flexible beam 130 and a second flexible beam 132. The beams 130, 132 are joined to each other at ends 136 and 134. The switch actuator 35 has barbs 142 that engage the walls 122 in the switch panel 15 to prevent the switch actuator 35 from falling out. The barbs 124 engage the end 136 of the switch actuator 35. The switch 34 fits in an opening 145 in the switch actuator 35, and the post 125 fits in an opening 137.
The switch is shown in the off position in
While the principles of the invention have been described above in connection with specific apparatus and applications, it is to be understood that this description is made only by way of example and not as a limitation on the scope of the invention.
Patent | Priority | Assignee | Title |
10814506, | Jan 28 2015 | KONINKLIJKE PHILIPS N V | Hair clipping device |
D981043, | Dec 12 2022 | E MISHAN & SONS, INC | Shaver |
ER3680, | |||
ER5593, | |||
ER8925, |
Patent | Priority | Assignee | Title |
1572644, | |||
2323046, | |||
2716279, | |||
2802260, | |||
2916821, | |||
2946123, | |||
3035346, | |||
3369294, | |||
3604112, | |||
3611566, | |||
3699652, | |||
4219931, | Jan 04 1978 | GESELLSCHAFTSVERTRAG UBER DIE ERFINDERGEMEINSCHAFT OPTIMARA, | Vacuum hair trimmer |
4314405, | Apr 24 1980 | Hair cutting device | |
4417397, | Jun 15 1981 | Matsushita Electric Works, Ltd. | Electric shaver |
4581822, | Dec 15 1983 | Kyushu Hitachi Maxell, Ltd. | Electric hair clipper |
4622745, | Sep 28 1984 | WAHL CLIPPER CORPORATION, CORP OF IL | Hair trimming apparatus |
4776095, | Nov 14 1985 | Matsushita Electric Works, Ltd. | Hair clipper |
5012576, | Jul 18 1990 | Personal hair trimmer | |
5050305, | Sep 13 1985 | Remington Corporation, LLC | Hair trimmer with comb attachment |
5075971, | Jul 17 1990 | Wahl Clipper Corporation | Methods and apparatus for trimming hair and disposing of hair clippings |
5084974, | Jan 22 1991 | ANDIS COMPANY | Clipper with lever actuated adjustable comb |
5724736, | Nov 05 1996 | Hair cutting device | |
5970616, | Dec 22 1997 | Wahl Clipper Corporation | Hair trimmer with lighted rotating head |
6261161, | Jan 06 1999 | Premark FEG L.L.C. | Sharpener assembly for a food slicer and related method |
6546592, | Jul 17 1999 | Black & Decker Inc | Dual filter vacuum cleaner apparatus |
6665938, | Dec 14 2000 | WAHL CIIPPER CORPORATION | Hair clipping device with adjustable deflecting comb assembly |
6684511, | Dec 14 2000 | Wahl Clipper Corporation | Hair clipping device with rotating bladeset having multiple cutting edges |
6739053, | Dec 14 2000 | Wahl Clipper Corporation | Hair clipping device with internal vacuum |
6934994, | May 22 2002 | Samsung Gwangju Electronics Co., Ltd. | Vacuum cleaner |
6978547, | Feb 14 2001 | Beard trimmer with internal vacuum | |
6986206, | Dec 14 2000 | Wahl Clipper Corporation | Hair clipping device with rotating bladeset having multiple cutting edges |
7076878, | Feb 14 2001 | Beard trimmer with internal vacuum | |
8484853, | Aug 29 2005 | Hair cutting device with vacuum hair collection system | |
20020073549, | |||
20060042103, | |||
20060162516, | |||
20060230619, | |||
20110308035, | |||
D294407, | Aug 19 1985 | Braun Aktiengesellschaft | Hair clipper with cutting cap |
D472674, | Dec 14 2000 | Wahl Clipper Corporation | Hair trimmer with vacuum |
DE19508462, | |||
DE3330741, | |||
EP1216799, | |||
JP1176646, | |||
JP200061174, | |||
JP3005899, | |||
JP751472, | |||
WO2004002690, | |||
WO9533600, |
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Mar 30 2017 | SNOW, GARY | Wahl Clipper Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 041802 | /0026 |
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